Light therapy system including spectacle frames and contact lenses

ABSTRACT

The present invention provides for eyeglasses used together with contact lenses to deliver light therapy to the wearer. The eyeglass lenses or frames feature an embedded light source in logical and electrical communication with power, sensors, processors, and other components contained within the eyeglasses. The eyeglass lenses or frames project light into complimentary contact lenses which refract, diffract or reflect light into the wearer&#39;s eyes.

RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent ApplicationSer. No. 61/439,401 filed Feb. 4, 2011; the contents of which are reliedupon and incorporated by reference.

FIELD OF USE

This invention describes a light therapy delivery mechanism fortreatment of seasonal affective disorder (SAD) and other purposes. Morespecifically, in some embodiments, the invention provides eyeglasses orcontact lenses or both including features for intelligent delivery oflight therapy.

BACKGROUND

Seasonal affective disorder (SAD) is a well-established mood disorderwherein sufferers experience depressive symptoms in a certain season ofthe year, most frequently during winter months. Those affected by SADoften have normal mental health during most of the year. Symptoms of SADmay include, but are not limited to, excessive sleeping, lack of energy,craving carbohydrates, difficulty concentrating, and withdrawal fromsocial activities. The symptoms result in feelings of depression,hopelessness, pessimism, and lack of pleasure.

Seasonal mood variations are believed to be related to changes inexposure to light. Geographic areas, such as the Arctic region, thatexperience fewer daylight hours, lower sunlight intensity, orsignificant periods of overcast skies exhibit a greater incidence ofSAD. Variations in prevalence of SAD within the adult population areevident within the United States, ranging from low rates in Florida andother sunny states to notably higher rates in Alaska, New Hampshire andother northern or overcast areas.

Light therapy has been researched and established as a prominent andeffective treatment for classic, or winter-based, seasonal affectivedisorder. Light therapy employs a device which emits significantly morelumens than a standard incandescent lamp. Common implementations includethe preferred bright white full spectrum light at 10,000 lux, oroptionally blue light at a wavelength of 480 nm at 2,500 lux, or greenlight at a wavelength of 500 nm at 350 lux. Light therapy normallyrequires a patient to sit with their eyes open at a prescribed distancefrom the light source for thirty to sixty minutes each day. Thisseasonal treatment is maintained for several weeks until the patientexperiences frequent exposure to natural light. A majority of patientsfind the therapy inconvenient and a considerable percentage, in somestudies up to 19%, therefore stop treatment. New methods and approachesare therefore desirable to deliver light therapy in a more convenient,continuous, and intelligent manner.

SUMMARY

Accordingly, the present invention includes eyeglasses capable ofdelivering light therapy to the wearer. The eyeglass lenses or framesfeature an embedded light source in logical and electrical communicationwith power, sensors, processors, and other components contained withinthe temple of the eyeglasses.

In addition, in some embodiments, eyeglass lenses or frames projectlight into complimentary contact lenses which refract or diffract thelight into the wearer's eyes.

In still another aspect, in some embodiments, spectacle frames providesensors and power which are in wireless communication with contactlenses containing a light source for the light therapy.

Finally, contact lenses may include embedded light sources as well assupporting electronics. Eyeglasses are not included in this embodiment.

DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a back view of eyeglasses with light sources embeddedin the lenses and with supporting electronics contained within thetemple according to some embodiments of the present invention.

FIG. 2 illustrates a front view of eyeglasses with light sourcesembedded in the lenses according to some embodiments of the presentinvention.

FIG. 3 illustrates a close-up view of an eyeglass lens with embeddedlight sources according to some embodiments of the present invention.

FIG. 4 illustrates a close-up view of an eyeglass lens with embeddedlight sources mounted in spectacle frames according to some embodimentsof the present invention.

FIG. 5 illustrates a portion of an eyeglass temple piece housingsupporting electronics according to some embodiments of the presentinvention.

FIG. 6 illustrates a portion of an eyeglass temple piece opened to showsupporting electronics according to some embodiments of the presentinvention.

FIG. 7 illustrates one side of supporting electronics from within aneyeglass temple piece according to some embodiments of the presentinvention.

FIG. 8 illustrates a second side of supporting electronics from withinan eyeglass temple piece according to some embodiments of the presentinvention.

FIG. 9 illustrates a bottom view of eyeglasses with light sourcesembedded in the frame according to some embodiments of the presentinvention.

FIG. 10 illustrates a cross-section view of an eyeglass lens withembedded light sources directing light into a complimentary contact lensaccording to some embodiments of the present invention.

FIG. 11 illustrates a cross-section view of eyeglasses with supportingelectronics in wireless communication with contact lenses containinglight sources according to some embodiments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention includes methods and apparatus for deliveringlight therapy using eyeglasses with embedded light sources. In addition,the present invention includes delivering light therapy using acombination of eyeglasses and complimentary contact lenses. The presentinvention also encompasses delivering light therapy using only contactlenses with embedded light sources.

In the following sections detailed descriptions of embodiments of theinvention will be given. The description of both preferred andalternative embodiments are exemplary embodiments only, and it isunderstood that to those skilled in the art that variations,modifications and alterations may be apparent. It is therefore to beunderstood that said exemplary embodiments do not limit the scope of theunderlying invention.

GLOSSARY

In this description and claims directed to the presented invention,various terms may be used for which the following definitions willapply:

Complimentary contact lens: as used herein refers to contact lenses andeyeglasses with special features used together to deliver light therapy.

Contact lens: refers to any ophthalmic device that resides in or on theeye. These devices can provide optical correction or may be cosmetic.For example, the term lens can refer to a contact lens, intraocularlens, overlay lens, ocular insert, optical insert or other similardevice through which vision is corrected or modified, or through whicheye physiology is cosmetically enhanced (e.g. iris color) withoutimpeding vision. In some embodiments, the preferred lenses of theinvention are soft contact lenses made from silicone elastomers orhydrogels, which include but are not limited to silicone hydrogels, andfluorohydrogels.

Intelligent light therapy: as used herein refers to a method ofdelivering light therapy whereby a processor evaluates various data and,based on data analysis, dynamically makes compensating adjustments to aprogrammed light therapy schedule. Adjusting light therapy based on theuser's exposure to ambient light is one example of intelligent lighttherapy.

Light therapy: as used herein refers to exposure to specific wavelengthsof light, controlled with various devices, and administered for aspecified amount of time, at a specified intensity, and, in some cases,at a specified time of day.

Lux: as used herein refers to units of illumination in the InternationalSystem of Units (SI). Lux provides a measure of luminous power per area.One lux is the amount of illumination provided when one lumen is evenlydistributed over an area of one square meter. This is also equivalent tothe illumination that would exist on a surface all points of which areone meter from a point source of one international candle. One lux isequal to 0.0929 foot-candle.

Optical Zone: as used herein refers to an area of an ophthalmic lensthrough which a wearer of the ophthalmic lens sees.

Programmed light therapy schedule: as used herein refers to a set ofautomated instructions that controls light therapy timing, duration andintensity based on variables such as dates, geographic region, andseverity of a user's seasonal affective disorder symptoms. A programmedlight therapy schedule may be set by an eye care professional, a medicaldoctor, or a user.

Seasonal Affective Disorder (SAD): as used herein refers to a mooddisorder that occurs during seasons when exposure to sunlight islimited, characterized by symptoms of depression and relieved by thearrival of spring or by light therapy. A recurrent state of depression,usually experienced by people in winter, thought to be related to lackof sunlight.

Referring now to FIG. 1, a back view of spectacle frames 101 with lightsources 102 embedded in lenses 103 is illustrated. Light sources 102 mayalso be mounted on the surface of lenses 103. Light sources 102 mayinclude light-emitting diodes (LEDs) or other lights which emit bluelight at wavelengths of 450 to 500 nanometers, most preferably at 470 to480 nanometers, and at 2,000 to 3,000 lux. Alternatively, LEDs or otherlights may emit green light at wavelengths of 475 to 525 nanometers,most preferably at 490 to 510 nanometers, and at 300 to 400 lux.Additionally, the light source 102 may be secured in any other mannerwhich allows

In another embodiment, a single light source may be piped to one or morelocations within an eyeglass lens 103 or eyeglass frame 101 to provideillumination. Light pipes may include, for example, fiber opticpathways.

An example of illuminated light sources is illustrated at 104. A lightsource 102 provides illumination toward a wearer's eyes such that anillumination is not obvious to an observer.

In another embodiment, light sources 102 are positioned such that lightis directed into a lens 103. A lens 103 may include light scatteringproperties in areas where light is specifically directed or lightscattering properties throughout a lens 103. Light scattering areas mayinclude diffractive properties, refractive properties, reflectiveproperties or any combination of diffractive, refractive and reflectiveproperties. Light scattering areas act to diffuse light, achievingpresentation of a soft glow rather than a glaring ray before a user'seye. In some preferred embodiments, light scattering areas may form aring within a perimeter area of an eyeglass lens 103 and may include aninternal barrier between a light scattering area and an optical zone ina central portion of a lens 103. An internal barrier prevents lightintended for light therapy from being dispersed into an optical zone ofa lens 103, minimizing the effect of light therapy luminescence onnormal vision. In still other embodiments, an entire lens 103 includeslight scattering properties designed such that it disperses only lightof wavelengths emitted by embedded light sources 102. This embodimentsupports maximum dispersion of light wavelengths intended for lighttherapy while not causing dispersion of light wavelengths that wouldaffect normal vision. A lens 103 may include a coating which shieldslight therapy luminescence from being readily noticed by an observerwhile not diminishing a user's light therapy or vision.

In the present embodiment, light sources 102 are connected to oneanother via conductive paths 105. Conductive paths 105 may be wiresembedded within a lens 103, or may be a conductive material, such as,for example, gold, copper, silver or other metal or conductive fiberapplied to a surface of a lens 103 via pad printing, sputter coating,vapor deposition or other known method. Conductive paths 105 are inelectrical and logical communication with supporting electronicscontained within one or both temple pieces 109. In some embodiments,supporting electronics are miniaturized such that they may be containedin other areas of eyeglasses, such as, for example, in areas near ahinge 107, within a frame above a lens 108, within a bridge 110, withinan earpiece 111, or other area.

One or more light sensors 106 are used to detect ambient white light,blue light or green light. Light sensors 106 may be located within aneyeglass frame 101 near a hinge 107, within a frame above a lens 108,within a temple piece 109, within a bridge 110, or other appropriatearea where a sensor 106 will not be obstructed, such as by hair. A lightsensor 106 is in electrical and logical communication with supportingelectronics contained within one or both temple pieces 109 or other areaof eyeglasses.

In some embodiments, a user control element 112, such as a switch orbutton, is provided to allow a user to adjust timing, duration andintensity of light therapy. One or more user control elements 112 may bepresent in temple pieces 109 or other areas of eyeglasses, such as, forexample, in areas near a hinge 107, within a frame above a lens 108,within a bridge 110, within an earpiece 111, or other area. Someembodiments provide for a basic operational state, wherein light therapyis controlled manually by a user starting and stopping therapy atappropriate times.

According to the present embodiment, a programmed light therapy schedulemay, for example, automatically adjust light therapy timing, durationand intensity based on variables such as dates, geographic region, andseverity of a user's seasonal affective disorder symptoms. A programmedlight therapy schedule may be set by an eye care professional, a medicaldoctor, or a user. During programmed light therapy, it may be desirablefor a user to adjust light intensity based on an activity, such as, forexample, decreasing light intensity when reading, working on a computer,or driving. Conversely, it may be desirable to increase light intensityduring work breaks, lunch break, or other less visually active times. Insome embodiments, intelligent light therapy is delivered when aprocessor evaluates manual changes to a programmed light therapyschedule and provides compensating adjustments in duration and intensityof treatment. In still other embodiments, intelligent light therapy isachieved when data from light sensors 106 is analyzed by a processor anda programmed light therapy schedule is dynamically adjusted based on awearer's exposure to ambient light.

In another embodiment of the present invention, a user may manuallyadjust light therapy based on the results of blood testing for melatoninlevels. Melatonin produced by the pineal gland is inhibited by light andincreases with darkness. Higher levels of melatonin promote sleepinessand lethargy, symptoms of seasonal affective disorder. Analysis of thelevel of melatonin in a patient's blood may be used as a guide toincrease or decrease light therapy.

In still other embodiments, a user may manually adjust light therapy tointentionally alter their sleep cycle. The use of light therapy forsleep cycle alteration may be valuable for persons working night shifts,for persons travelling to significantly different time zones, formilitary personnel preparing for night operations, and other uses.Additionally, light therapy initiated by the user upon awakening may beused to treat circadian rhythm disorders such as delayed sleep phasesyndrome (DSPS) and non-24-hour sleep-wake syndrome.

Referring now to FIG. 2, a front view of spectacle frames 201 with lightsources 202 embedded in lenses 203 is illustrated. Light sources 202 areconnected to one another via conductive paths 204.

Referring now to FIG. 3, illustrated is a close-up view of a singleeyeglass lens 301 with embedded light sources 302 connected viaconductive paths 303. While the embodiment described in this applicationshows eight light sources 302 per lens 301, other embodiments mayinclude fewer or more light sources 302 per lens 301 and may includelight sources 302 in varying locations and patterns within a lens 301.To provide a sense of scale, a lens 301 is shown placed over a standardU.S. quarter dollar coin 304. Not shown in this diagram is a mechanismfor providing electrical communication between the light sources 302 andsupporting electronics. Electrical communication may be provided, forexample, via a conductive contact between a source located in a templeof a pair of eyeglasses, via a conductive wire, a conductive ribbonwire, or via wireless modes, such as inductance. Inductance may beaccomplished, for example, via an antenna located in the lens or thelens frame and a power source transmitting power from a temple piece orother proximate location to the antenna.

Referring now to FIG. 4, a close-up view of a single eyeglass lens 401with embedded light sources 402 connected via conductive paths 403 isillustrated mounted into an eyeglass frame 404.

Referring now to FIG. 5, illustrated is a close-up view of a portion ofan eyeglass temple piece 501 which houses supporting electronics. Thetemple piece 501 is not fully closed as evidenced by a gap 502. A USBconnector 503 is used for electrical connection, such as, for example,charging batteries within a temple piece 501. A USB connector 503 isalso used for logical communication, such as, for example, loading auser-specific programmed light therapy schedule or offloading usage andsensor data stored by supporting electronics. A hinge area 504 isvisible, at which point a temple piece 501 connects to an eyeglassframe. For scale purposes, a temple piece 501 is shown adjacent to astandard U.S. quarter dollar coin 505.

Referring now to FIG. 6, a close-up of an eyeglass temple piece 601 isnow illustrated with a top half of a supporting electronics casing 602removed. A circuit board containing supporting electronics 603 isdisplayed including batteries 604, a processor 605 and a USB connector606. Wiring 607 provides logical and electrical communication betweensupporting electronics 603 and other components such as light sourcesand light sensors. A hinge area 608 is visible, where a temple piece 601connects to an eyeglass frame. To provide a sense of scale, a templepiece 601 is shown adjacent to a standard U.S. quarter dollar coin 609.

Referring now to FIG. 7, a top down view of a first side of a circuitboard containing supporting electronics 701 is illustrated. The circuitboard 701 is shown removed from a casing in which it was depicted inFIGS. 5 and 6. A circuit board 701 includes batteries 702, a processor703, power terminals 704, and a USB connector 705. Wiring 706 attachedto power terminals 704 provides logical and electrical communicationbetween supporting electronics on a circuit board 701 and othercomponents such as light sources and light sensors. A processor 703 maybe used, for example, to run programmed light therapy schedules storedin memory, to analyze light sensor data and determine a unique lighttherapy schedule based on the wearer's exposure to ambient light, toevaluate manual changes to a programmed light therapy schedule andprovide compensating adjustments, and to analyze light source and lightsensor data to detect device failures. Power terminals 704 enableconnection of wiring 706, allowing logical and electrical communicationbetween supporting electronics on a circuit board 701 and othercomponents such as light sources and light sensors. To provide a senseof scale, a circuit board 701 is shown adjacent to a standard U.S.quarter dollar coin 707.

Referring now to FIG. 8, illustrated is a top down view of a second sideof a circuit board containing supporting electronics 801. The circuitboard 801 is shown removed from a casing in which it was depicted inFIGS. 5 and 6. A circuit board 801 includes memory 802, capacitors 803,and power terminals 804. The USB connector of FIG. 7 (705) is seen inFIG. 8 at 805. For scale, a circuit board 801 is shown adjacent to astandard U.S. quarter dollar coin 806. Memory 802 may be used, by way ofnon-limiting example, to store pre-programmed light therapy schedules,to store data captured by light sensors, to store actual light therapydates, times, durations and intensities, and to store data related tolight source and light sensor operation in order to detect devicefailures.

Referring now to FIG. 9, illustrated is a bottom view of an eyeglassframe 901 with light sources 902 embedded in the eyeglass frame 901above lenses 903. Light sources 902 may be embedded within an eyeglassframe 901, or may be mounted on a surface of an eyeglass frame 901.Light sources 902 are connected to one another by conductive paths, notillustrated in FIG. 9. Conductive paths may be wires embedded within aneyeglass frame 901, or may be a conductive material, such as, forexample, gold, silver, copper or other metallic material or conductivefiber applied to the surface of an eyeglass frame 901 via pad printing,sputter coating, vapor deposition or other known method. Conductivepaths allow light sources 902 to be in electrical and logicalcommunication with supporting electronics housed within one or bothtemple pieces 904. In some embodiments, supporting electronics areminiaturized such that they may be contained in other eyeglass areas,such as, for example, in areas near a hinge 905, within a frame above alens 901, within a bridge 906, within an earpiece (not shown in FIG. 9),or other area. Light sources 902 are positioned so that light isdirected onto lenses 903. Lenses 903 may include light scatteringproperties in areas where light is specifically directed or lightscattering properties throughout the lens. Light scattering areas mayinclude diffractive properties, refractive properties, reflectiveproperties or any combination of diffractive, refractive and reflectiveproperties. Light scattering areas act to diffuse light, achievingpresentation of a soft glow rather than a glaring ray before a user'seye. Lenses 903 may include a coating which shields light therapyillumination from being readily noticed by an observer while notaffecting a user's light therapy or vision.

Referring now to FIG. 10, an embodiment including a complimentarycontact lens is illustrated. A cross-section view 1000 includes aneyeglass lens 1001 with embedded light sources 1002 directing light 1003into light scattering areas 1004 of a complimentary contact lens 1005. Alight scattering area 1004 results in light 1006 being dispersed acrossa cornea 1007 of an eye 1008. A light scattering area 1004 may includediffractive properties, refractive properties, reflective properties orany combination of diffractive, refractive and reflective properties.

In some embodiments, a cross-section view 1000 may be a top-down view,wherein one or more embedded light sources 1002 are placed near thesides of an eyeglass lens 1001. In other embodiments, a cross-sectionview 1000 may be a side view, such that one or more embedded lightsources 1002 are placed near the top and bottom of an eyeglass lens1001. In still other embodiments, embedded light sources 1002 may beembedded in or mounted on an eyeglass frame rather than an eyeglass lens1001. Embedded light sources 1002 include light-emitting diodes (LEDs)or other light sources 1002 emitting light 1003 for light therapy. Lightsources 1002 may include light-emitting diodes (LEDs) or other lightswhich emit blue light at wavelengths of 450 to 500 nanometers, mostpreferably at 470 to 480 nanometers, and at 2,000 to 3,000 lux.Alternatively, LEDs or other lights may emit green light at wavelengthsof 475 to 525 nanometers, most preferably at 490 to 510 nanometers, andat 300 to 400 lux. Another embodiment includes a single light sourcefrom which light is piped to one or more locations within an eyeglasslens 1001 or eyeglass frame to provide illumination.

Supporting electronics, not shown, are contained in an eyeglass frameand include components such as, for example, light sensors, batteries,capacitors, memory, processors, and a USB connector. Supportingelectronics are in logical and electrical communication with lightsources 1002. Electrical communication may be provided, for example, viaa conductive contact between a source located in a temple of a pair ofeyeglasses, via a conductive wire, a conductive ribbon wire, or viawireless modes, such as inductance. Inductance may be accomplished, forexample, via an antenna located in the lens or the lens frame and apower source transmitting power from a temple piece or other proximatelocation to the antenna.

In some embodiments, light scattering areas 1004 of a complimentarycontact lens 1005 form a ring within a perimeter area of a complimentarycontact lens 1005 such that directed light 1003 need not strike alimited target area. The orientation of a complimentary contact lens1005 on an eye 1008 relative to light sources 1002 within an eyeglasslens 1001 is therefore inconsequential when light 1003 is directedtoward a light scattering area 1004 continuously present around aperimeter area of a complimentary contact lens 1005.

In some preferred embodiments, a complimentary contact lens 1005 mayinclude an internal barrier between a light scattering area 1004 and anoptical zone in a central portion of a lens. An internal barrierprevents light 1003 intended for light therapy from being dispersed intoan optical zone of a complimentary contact lens 1005. In this way, light1003 intended for light therapy is only dispersed around a perimeter ofa cornea 1007, minimizing its effect on normal vision.

In still other embodiments, an entire complimentary contact lens 1005includes light scattering properties such as diffraction, refraction andreflection. Light scattering properties are designed such that theydisperse only light 1003 of wavelengths emitted by embedded lightsources 1002. This embodiment supports maximum dispersion of light 1003wavelengths intended for light therapy within an eye 1008 while notcausing dispersion of light wavelengths that would affect normal vision.

Referring now to FIG. 11, an embodiment is illustrated including aneyeglass frame and a complimentary contact lens. A cross-section view1100 includes an eyeglass frame 1101 containing supporting electronics1102. Supporting electronics 1102 may include components such as, forexample, light sensors, batteries, capacitors, memory, processors, and aUSB connector. Supporting electronics 1102 are in wireless communication1103 with a complimentary contact lens 1105 containing embedded lightsources 1104 directing light 1106 onto a cornea 1107 of an eye 1108.Supporting electronics 1102 may be placed in various locations embeddedin or mounted on an eyeglass frame 1101. In other embodiments,supporting electronics 1102 may be included in jewelry, hats, clothing,or other items worn by a user such that light sensors detect ambientlight experienced by the user and supporting electronics 1102 are near acomplimentary contact lens 1105 for purposes of wireless communication.Wireless modes of communication may include, for example, inductance.Inductance may be accomplished via an antenna located in a complimentarycontact lens 1105 and a power source transmitting power from an eyeglassframe 1101, jewelry, clothing, or other item proximate to the antenna.

In some embodiments of the present invention, a cross-section view 1100may be a top-down view, wherein supporting electronics 1102 are placednear the sides of an eyeglass frame 1101. In other embodiments, across-section view 1100 may be a side view, such that supportingelectronics 1102 are placed near the top and bottom of a side of aneyeglass frame 1101. A number of embedded light sources 1104 and anarrangement of embedded light sources 1104 around a perimeter of acomplimentary contact lens 1105 may vary. Embedded light sources 1104include light-emitting diodes (LEDs) or other light sources 1104emitting light 1106 for light therapy. Light sources 1104 may includelight-emitting diodes (LEDs) or other lights which emit blue light atwavelengths of 450 to 500 nanometers, most preferably at 470 to 480nanometers, and at 2,000 to 3,000 lux. Alternatively, LEDs or otherlights may emit green light at wavelengths of 475 to 525 nanometers,most preferably at 490 to 510 nanometers, and at 300 to 400 lux. Anotherembodiment includes a single light source from which light is piped toone or more locations within a complimentary contact lens 1105 toprovide illumination.

In some embodiments, light sources 1104 may direct light 1106 into aninterior portion of a complimentary contact lens 1105 in which the lightsources 1104 are embedded. Light 1106 may be directed into a lightscattering area, not depicted, including diffractive properties,refractive properties, reflective properties, or any combination ofdiffractive, refractive and reflective properties. A light scatteringarea may form a ring within a perimeter area of a complimentary contactlens 1105. Light 1106 striking a light scattering area causes agenerally broad dispersion of light 1106 onto a cornea 1107 of an eye1108.

In some preferred embodiments, a complimentary contact lens 1105 mayinclude an internal barrier between a light scattering area around aperimeter of a lens and an optical zone in a central portion of a lens.An internal barrier prevents light 1106 intended for light therapy frombeing dispersed into an optical zone of a complimentary contact lens1105. In this way, light 1106 intended for light therapy is onlydispersed around a perimeter of a cornea 1107, minimizing its effect onnormal vision.

In still other embodiments, an entire complimentary contact lens 1105includes light scattering properties such as diffraction, refraction orreflection. Light scattering properties are designed such that theydisperse only light 1106 of wavelengths emitted by embedded lightsources 1104. This embodiment supports maximum dispersion of light 1106wavelengths intended for light therapy within an eye 1108 while notcausing dispersion of light wavelengths that would distort vision.

CONCLUSION

The present invention, as described above and as further defined by theclaims below, provides methods and apparatus for delivering lighttherapy using eyeglasses with embedded light sources, using eyeglassesand complimentary contact lenses, or using contact lenses with embeddedlight sources.

1. An apparatus for administering light therapy, the apparatuscomprising: a spectacle frame suitably sized for wearing on a humanbeing and securing one or more optical lenses; one or more light sourcesfixedly mounted to provide light onto a contact lens on an eye of awearer of the spectacle frame; and a contact lens comprising a portionfor receiving the light provided.
 2. The apparatus of claim 1 whereinthe light source emits blue light at wavelengths of 450 to 500nanometers.
 3. The apparatus of claim 2 wherein the light source emitsblue light at wavelengths of 470 to 480 nanometers.
 4. The apparatus ofclaim 3 wherein the light source emits between about 2,000 to 3,000 luxof light.
 5. The apparatus of claim 1 wherein the light source emitsgreen light at wavelengths of 475 to 525 nanometers.
 6. The apparatus ofclaim 5 wherein the light source emits green light at wavelengths of 490to 510 nanometers.
 7. The apparatus of claim 6 wherein the light emitsbetween about 300 to 400 lux of light.
 8. The apparatus of claim 1wherein the light source comprises one or more light emitting diodes. 9.The apparatus of claim 8 wherein apparatus comprises one or light pipes.10. The apparatus of claim 9 wherein the one or more light pipescomprise fiber optic pathways.
 11. The apparatus of claim 4 wherein thelight source emits the blue light onto at least a portion of the one ormore optical lenses.
 12. The apparatus of claim 7 wherein the lightsource emits the blue light onto at least a portion of the one or moreoptical lenses.
 13. The apparatus of claim 1 additionally comprising amechanism for controlling an amount of light provided to the eye of thewearer of the spectacle frame.
 14. The apparatus of claim 13 wherein themechanism for controlling an amount of light may be adjusted by thewearer of the spectacle frame.
 15. The apparatus of claim 13 wherein themechanism for controlling an amount of light may be adjusted by aprocessor executing digital software.
 16. The apparatus of claim 13wherein the mechanism for controlling an amount of light may be adjustedbased upon an amount of melatonin measured in the blood of a wearer ofthe spectacle frames.
 17. The apparatus of claim 13 wherein themechanism for controlling an amount of light may be adjusted based uponan amount of ambient light to which a wearer of the spectacle frames isexposed.
 18. The apparatus of claim 17 additionally comprising a sensorattached to the spectacle frame for measuring an amount of ambientlight, wherein the sensor provides an electrical signal to the processorindicative of an amount of ambient light.
 19. The apparatus of claim 1additionally comprising a power source in electrical communication withthe one or more lights sources.
 20. The apparatus of claim 19 whereinthe power source comprises a rechargeable battery.
 21. The apparatus ofclaim 1 wherein the contact lens comprises a portion for diffracting thelight received from the light source.
 22. The apparatus of claim 1wherein the contact lens comprises a portion for focusing the lightreceived from the light source.
 23. An apparatus for administering lighttherapy, the apparatus comprising: a spectacle frame suitably sized forwearing on a human being and securing one or more optical lenses; one ormore energy sources fixedly mounted to the spectacle frame and capableof providing power to a contact lens on an eye of a wearer of thespectacle frame; and a contact lens comprising a light source powered bythe power provided by the energy source.
 24. The apparatus of claim 23wherein the light source emits blue light at wavelengths of 450 to 500nanometers.
 25. The apparatus of claim 24 wherein the light source emitsblue light at wavelengths of 470 to 480 nanometers.
 26. The apparatus ofclaim 25 wherein the light source emits between about 2,000 to 3,000 luxof light.
 27. The apparatus of claim 23 wherein the light source emitsgreen light at wavelengths of 475 to 525 nanometers.
 28. The apparatusof claim 27 wherein the light source emits green light at wavelengths of490 to 510 nanometers.
 29. The apparatus of claim 28 wherein the lightemits between about 300 to 400 lux of light.
 30. The apparatus of claim23 wherein the light source comprises one or more light emitting diodes.